RU2560082C2 - Method for frontal earth surface aperture synthesis with exclusion of blind zones in front zone using multi-position radar system - Google Patents

Abstract

FIELD: physics, navigation.

SUBSTANCE: invention relates to multi-position on-board radar stations and can be used to form a radar image of an area of the earth's surface under surveillance. Using anterolateral scanning, the frontal area of the earth's surface is synchronously irradiated with probing signals using two antennae on-board an aircraft, wherein receive/transmit positions, depending on the extent of the irradiated frontal area of the earth's surface, are at a distance d from each other such that irradiated neighbouring zones overlap and reflected signals, which are received by the two antennae on-board each of N aircraft, directed towards a given direction for left and right side anterolateral scanning, accumulate the reflected signals, and processing thereof results in two high-resolution radar images from the irradiated areas of the earth's surface in the direction of irradiation of the two antennae by using an aperture synthesis algorithm, after which on one of the N aircraft, radar images are synthesized via a communication channel from each of the N aircraft, thereby obtaining a high-resolution radar image in real time in the front zone, excluding blind zones.

EFFECT: high angular coordinate resolution.

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Description

The invention relates to a multi-position airborne radar with a synthesized aperture of the antenna, can be used in remote sensing systems for the formation of a radar image (RLI) of the observed area of the earth’s surface in azimuth distance-azimuth coordinates at the direction of movement of the aircraft.

Known methods for producing radar images in the front zone from the literature, including patent (1, 2, 3, 4).

These methods are well established and are widely used at present. However, they have the following limitations:

1) low resolution in angular coordinate;

2) the presence of blind zones during frontal synthesis (at an azimuthal angle of ± 10 ° due to a slight difference in this zone of the Doppler frequency shift of the reflected signal);

3) insufficient information content of single-position systems.

The closest in essence to the claimed invention should include the method according to the patent for the invention of the Russian Federation No. 2278398 (5).

The sequence of operations when implementing the patented method is as follows:

1. N independent orthogonal signals S ₁ ... S _N are emitted from the board of the N transmitting positions (Rx).

2. Oriented radiation patterns (NAM) of all N transmitting positions on a given plot of the earth's surface.

3. The radiation pattern of the first receiving antenna is directed toward a given portion of the earth’s surface, and the beam patterns of the second weakly directed receiving antenna are oriented in the direction of N transmitting positions.

4. On board the receiving position using the antenna, oriented in the direction of a given plot of the earth's surface, N orthogonal signals S _1OTP ... S _{NOTP are received} , reflected from the observed plot of the earth's surface.

5. On board the receiving position using the antenna, oriented in the direction of the transmitting position, receive N orthogonal signals of direct propagation S _1PR ... S _NPR directly coming from N transmitting positions.

6. From the signals of direct propagation S _1PR ... S _NPR extract information about the status of each transmitter and its carrier and the state of the propagation medium.

7. On board the receiving position for each of the N pairs of direct and reflected signals corresponding to each other, N radar holograms are recorded corresponding to N different angles of irradiation of the observed portion of the earth's surface by each of the transmitter carriers.

8. On board the receiving position, N different angles of different radar images (RLS) of the observed area of the earth’s surface are simultaneously synthesized.

9. Perform a joint analysis of a set of N different radar images.

The patent decision includes similar features: from 2 to N dual-antenna systems, airborne radar stations, devices for providing a communication channel. The main limitations of this method are:

1. The inability of this method to form an extended radar image in the front viewing area.

2. Low resolution in azimuthal coordinate.

Moreover, through the use of a two-antenna system, it is possible to reduce the number of transceiver positions (IFR) on board an aircraft as part of a multi-position radar system.

A method is proposed to avoid these limitations.

The essence of the proposed method is as follows. Unlike the prototype, the method is implemented using N combined IFRs located on each of the N aircraft. In addition, an aperture synthesis algorithm is used in the anterolateral view, which makes it possible to increase the resolution in angular coordinate. The proposed method allows you to function in real time.

The problem to which the invention is directed is to eliminate blind spots during frontal synthesis of the aperture to form a radar image of the earth's surface in the front zone with high resolution in real-time angular coordinate.

This problem is solved due to the fact that the invention

“A method of front-end synthesis of an antenna aperture when surveying the earth’s surface with the exception of blind spots in the front zone using a multi-position radar system, including from 2 to N two-antenna systems with phased arrays, airborne radar stations, devices for providing a communication channel,

characterized in that

multi-position radar system

represents a group of single-position radar systems, which are transceiver positions (IFP) located on the boards of aircraft (LA), a device for providing a communication channel between the IFR, while

the frontal portion of the earth’s surface is synchronously irradiated with sounding signals using the two-antenna system of each of the SPPs through the anterolateral view, and the SPPs are at a distance d from each other and are located so that the irradiated zones of the anterolateral view overlap,

reflected radar signals received by two-antenna systems, oriented in a given direction for the left and right anterolateral view of each aircraft, are used to synthesize the observed portion of the earth’s surface where the control center is located and information is processed,

collected through communication systems from other IFPs, resulting in the formation of the final front-end high-resolution radar image in real time in the front zone, while blind spots are eliminated along the direction of each aircraft. ”

EFFECT: obtaining high-resolution radar images of real-time radar data in the front view zone of the earth’s surface when synthesizing the aperture of a radar from an N LA board, excluding blind spots, using a multi-position airborne radar.

The invention is illustrated by a further description and drawings, in which: FIG. 1 - structural diagram of the front zone of the earth's surface, the number of SPP from 2 to N; FIG. 2 is a structural diagram of a transceiver position, which includes a two-antenna system, an airborne radar station, a synchronization device, a device for providing a communication channel for exchanging information between the IFR and the information processing and control center; FIG. 3 is a structural diagram of the exchange and transmission of information between a multi-position radar system and a center for processing and managing information; FIG. 4 is a structural diagram of a control and information processing center.

The proposed method operates as follows. A signal is sent to the device from the command control unit to provide communication channels. The communication system sends control signals via communication channels to the aircraft, where, using these commands, the IFR control device generates the aircraft's trajectory to achieve the necessary IFR location, in particular to achieve the required distance between the aircraft. In addition, the control commands set the parameters for tuning the dual-antenna system, synchronizer, transmitter and receiver. After synchronous radiation, the signals reflected to the two-antenna system arrive at the corresponding receiver, then to the data processing processor, where the radar data is generated, and then, together with the navigation data, antenna parameters, and the transmitter, they are transmitted to the device providing the communication channel. With each of the N IFRs, information is transmitted to the communication system of the control and processing center, which is processed on a data processor, which forms the final radar image in the front viewing area.

In FIG. Figure 1 shows how, with a dual-antenna SPT, synchronously irradiate a portion of the earth’s surface with sounding signals in such a way as to irradiate the entire front edge of the earth’s surface using an anterolateral view with overlapping observation zones of neighboring SPTs.

It should be noted that the processing and control center can be based on one of the aircraft with additional equipment in accordance with FIG. 4 or at a ground station.

A manned aircraft, an unmanned aerial vehicle, can be used as an IFR carrier.

Information sources

1. Earth observation radar / under. ed. G.S. Kondratenkova. - M.: Radio and Communications, 1983 .-- 272 p.

2. Multifunctional radar systems, ed. B.G. Tatarsky, M., Drofa LLC, 2007, pp. 24, 25, 174-195.

3. A method of observing the earth's surface in the front viewing area of an airborne radar - RF patent No. 2419109 IPC G01S 13/89, publ. 05/20/2011.

4. A method of mapping the earth's surface by an airborne radar station - RF patent No. 2423724, IPC G01S 13/89, publ. 07/10/2011.

5. A method of obtaining a radar image of the earth's surface using a multi-position radar system with a synthesized aperture of the antenna - RF patent No. 2278398, IPC G01S 13/90, VV 9/04, publ. 06/20/2006.

Claims (1)

The method of front-end synthesis of the antenna aperture during the survey of the earth's surface with the exception of blind spots in the front zone using a multi-position radar system, including from 2 to N two-antenna systems with phased arrays, airborne radar stations, devices for providing a communication channel,
characterized in that
multi-position radar system
represents a group of single-position radar systems, which are transceiver positions (IFP) located on the boards of aircraft (LA), a device for providing a communication channel between the IFR, while
the frontal portion of the earth’s surface is synchronously irradiated with sounding signals using the two-antenna system of each of the SPPs through the anterolateral view, and the SPPs are at a distance d from each other and are located so that the irradiated zones of the anterolateral view overlap,
reflected radar signals received by two-antenna systems, oriented in a given direction for the left and right anterolateral view of each aircraft, are used to synthesize the observed portion of the earth’s surface where the control center is located and information is processed,
collected through communication systems from other IFRs, resulting in the formation of the final front-end high-resolution radar image in real time in the front zone, while blind spots are eliminated along the direction of each aircraft.

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